Molecular cloning and expression of cDNAS encoding rat aldosterone synthase: variants of cytochrome P-450(11 beta)

Enzyme-activated inhibitors of steroidal hydroxylases

Cytochrome P450 monooxygenases (CYP450) of the steroid biosynthetic pathways are highly substrate specific in comparison to the variable specificities of hepatic CYP450 enzymes. Both groups of enzymes catalyze the reductive cleavage of molecular oxygen with transfer of oxygen to the substrate to form hydroxylated derivatives. Those steroids formed in endocrine tissues represent highly specific endocrine/autocrine hormones with enhanced biological potency, while hepatic hydroxylation of steroids reduces their endocrine bioactivities and enhances urinary elimination. Changes of the hormonal milieu of endocrine and peripheral tissues are associated with the development of hyperplastic and/or malignant conditions. Hormone deprivation induces regression of endocrine dependent growth via apoptosis and may also alter growth of hormone insensitive cells by the induction of negative growth factors. Biosynthetic CYP450 enzymes of those steroids that mediate specific disease processes are potential therapeutic targets for selective intervention. This objective can be accomplished by the design of specific pseudo-substrate analogs that will be activated during enzyme-directed catalysis to produce a reactive functional group in the enzyme's active site that will either tightly or irreversibly bind and inactivate the host enzyme. The CYP450 enzymes that hydroxylate the C19 carbon of androgens (aromatase) and the C18 carbon of corticosterone (aldosterone synthase) were selected as target enzymes because they are terminal enzymes of biosynthetic pathways which hydroxylate specific angular methyl groups. Hypersecretion of their respective hormonal products, estrogens and aldosterone, are associated with specific disease conditions. Substrate analogs containing ethynyl, vinyl, or nitrile groups attached to the C19 or C18 methyl groups were enzyme-activated inhibitors. The ethynyl analogs, 19-acetylenic androstenedione (Plomestane) and 18-acetylenic deoxycorticosterone, had nanomolar inhibitory constants (Ki values) and were irreversible inactivators of their target enzymes in animal models.

Aldosterone: the minority hormone of the adrenal cortex

In comparison with the glucocorticoids cortisol and corticosterone, the mineralocorticoid aldosterone is a minority hormone of the mammalian adrenal cortex, and its proper function is dependent upon protective physiological mechanisms. These include a particular site of aldosterone synthesis in zona glomerulosa cells as well as a complex multifactorial control system, which adapts aldosterone production to acute and chronic changes in body sodium and potassium contents, irrespective of pituitary ACTH secretion. In the course of the last few years, an important element of these mechanisms has been identified in the form of the enzyme involved in the final steps of aldosterone biosynthesis. In species such as the human, rat, and mouse, the conversion of deoxycorticosterone to aldosterone is catalyzed by an isozyme (CYP11B2) of cytochrome P450(11 beta) (CYB11B1). The gene encoding this enzyme is expressed only in the zona glomerulosa. Its transcription is enhanced by sodium deficiency and potassium intake, but is suppressed by long-term administration of high doses of ACTH. In contrast, the gene encoding CYP11B1, i.e., the major (non-aldosterone-producing) type of the enzyme, is expressed mainly in the zona fasciculata, and its expression depends on physiological concentrations of ACTH. In other animal species (cattle, pig), the major forms of cytochrome P450(11) beta have an inherent aldosterone-synthesizing activity, which is, however, selectively suppressed in mitochondria of zona fasciculata cells by yet unknown mechanisms.

The presence of two cytochrome P450 aldosterone synthase mRNAs in the hamster adrenal

We isolated a cDNA from a hamster adrenal cDNA library which was similar in sequence to those of the mouse and rat P450c18 cDNAs. The hamster P450c18 cDNA, however, was shorter than the rat and mouse P450c18 cDNAs at its 5'-end and the peptide leader sequence was absent. From a hamster genomic library we isolated and sequenced the first seven exons and a 5'-flanking region of the first P450c18 gene exon. With this information we were able to generate a P450c18 cDNA containing the peptide leader sequence using the polymerase chain reaction. Northern analyses were performed on adrenals from hamsters maintained on a low sodium diet for 0, 4, 7 and 10 days using a 32P-labeled sequence specific to P450c18; two mRNA bands were found at 2 and 3.4 kb. The intensity of both bands was increased about 3- to 5-fold under sodium restriction compared to controls. A distinct mRNA band of 2.3 kb hybridized with an oligonucleotide specific to P450(11) beta and its intensity did not change following low sodium intake. Immunoblotting analyses were performed using an antibovine adrenal P450(11) beta antibody that does not discriminate between P450(11) beta and P450c18 proteins. Three bands were detected at 52, 48 and 45 kDa in homogenate preparations of entire glands. Furthermore, the 45 kDa protein band was present in homogenates of the zona glomerulosa and absent in homogenates of the zone fasciculata-reticularis. In conclusion, these results show that the hamster adrenals express P450c18 as do mouse, rat and human adrenal glands. Furthermore, two P450c18 mRNAs, which are inducible by a low sodium intake, are present in the hamster adrenal vs one for the rat. The physiological role of these two hamster adrenal mRNA species remains to be elucidated.

Role of adrenal renin in the regulation of adrenal steroidogenesis by corticotropin

The major regulator of mineralocorticoid production in the adrenal is angiotensin II produced by the action of renal renin. The discovery that the rodent adrenal also synthesizes renin and angiotensinogen suggests there is autocrine regulation of mineralocorticoid synthesis. The transgenic rat [TGR(mREN2)27] expresses the Ren-2d gene predominantly in the adrenal. Despite suppressed kidney and plasma renin, these animals develop fulminant hypertension between 5 and 15 weeks of age. Corticosteroid concentrations are significantly elevated during hypertension development. We assessed steroidogenesis in TGR(mREN2)27 rats by analyzing the expression of the mRNAs for three steroidogenic enzymes: P450scc, the rate-limiting step of steroidogenesis; P450c11 beta, which converts deoxycorticosterone to corticosterone in the zona fasciculata/reticularis; and P450c11AS, which converts deoxycorticosterone to aldosterone in the zona glomerulosa. P450c11AS mRNA, but neither P450c11 beta nor P450scc mRNA, was overexpressed in the adrenal gland of TGR(mREN2)27 rats. In situ hybridization with specific probes for P450c11 beta and P450c11AS mRNA localized the former exclusively to the zona fasciculata and the latter to the zona glomerulosa. In TGR(mREN2)27 rats, the size of the adrenal and number of P450c11AS-expressing zona glomerulosa cells were about twice those of a normal Sprague-Dawley rat. Both animals respond to corticotropin similarly; corticotropin had no effect on the expression of P450scc and P45011 beta mRNAs, rendered P450c11AS mRNA undetectable, and simultaneously altered the morphology of the adrenal cortex, resulting in a lack of zona glomerulosa-like cells. Thus, the local renin-angiotensin system has a major effect on the basal expression of P450c11AS mRNA, but little effect on the corticotropin-regulated expression of P450scc, P450c11 beta, and P450c11AS mRNAs.

Separate induction of the two isozymes of cytochrome P-450(11) beta in rat adrenal zona glomerulosa cells

In the rat adrenal cortex, two isozymes of cytochrome P-450(11) beta (CYP11B1 and CYP11B2) have been identified. They are encoded by two different genes with a homology much higher in their coding than in their 5'-flanking regions. CYP11B1 is found in all the zones of the gland and catalyzes a single hydroxylation of deoxycorticosterone (DOC) in the 11 beta- or the 18-position. CYP11B2 is produced exclusively in the zona glomerulosa and catalyzes all three reactions involved in the conversion of DOC to aldosterone. In vivo and in vitro, the expression of the genes encoding CYP11B1 and CYP11B2 is regulated by two separate control systems which appear to operate both independently and interdependently. In vivo zona glomerulosa expression of CYP11B1 was enhanced by ACTH treatment or potassium depletion and was lowered by potassium repletion. CYP11B2 expression disappeared upon potassium depletion or ACTH treatment, but reappeared during potassium repletion. In vitro, only CYP11B1 activity was detectable and responsive to ACTH treatment in zona glomerulosa cells cultured at a potassium concentration of 6.4 mmol/l. Aldosterone biosynthetic activity and mRNA encoding CYP11B2 could be detected only after at least 1 day of exposure to a high extracellular potassium concentration (> or = 12 mmol/l).

18-Ethynyl-deoxycorticosterone inhibition of steroid production is different in freshly isolated compared to cultured calf zona glomerulosa cells

The inhibiting effects of 18-ethynyl-deoxycorticosterone (18-E-DOC) as a mechanism-based inhibitor on the late-steps of the aldosterone biosynthetic pathway were examined in calf adrenal zona glomerulosa cells in primary culture and in freshly isolated calf zona glomerulosa cells. 18-E-DOC inhibited the stimulated secretion of aldosterone and 18-hydroxycorticosterone in a similar dose-response and time fashion. No significant differences were found between the inhibition in cultured and freshly isolated cells (Ki of 0.25 vs 0.26 microM) Corticosterone secretion stimulated by ACTH or angiotensin II was also cultured in freshly isolated zona glomerulosa and fasciculata cells, but was not inhibited in cultured calf adrenal cells. Cortisol secretion stimulated by ACTH was not inhibited by 18-E-DOC in cultured zona fasciculata adrenal cells, but was inhibited in freshly isolated zona fasciculata cells with a Ki of 48 microM. The secretion of 18-hydroxyDOC or 19-hydroxyDOC stimulated by ACTH was not inhibited by 18-E-DOC. The bovine adrenal has been reported to have cytochrome P-450 11 beta-hydroxylases that can perform the various hydroxylations required for the synthesis of cortisol and aldosterone in the different areas of the adrenal. In other species a distinct 11 beta-hydroxylase which participates in the biosynthesis of aldosterone and is located in the zona glomerulosa has been described. These studies with the mechanism-based inhibitor, 18-E-DOC, suggest that the bovine adrenal functions in a manner very similar to that of other species and raises the possibility that a distinct 11 beta-hydroxylase with aldosterone synthase activity might be present, but has not been cloned as yet.

Angiotensin increases aldosterone synthase mRNA levels in human NCI-H295 cells

Understanding the regulation of aldosterone secretion has been hampered by the lack of a cell culture system that remains chronically responsive to angiotensin stimulation. NCI-H295 cells, cultured from a human adrenocortical tumor, express the three major pathways of adrenal steroidogenesis and produce small amounts of aldosterone during basal culture. We have determined changes in aldosterone production and in aldosterone synthase (AS, P45011B2) mRNA levels in these cells in response to angiotensin II (AII) and forskolin. Culture of NCI-H295 cells with 10(-7) M AII or with 10(-5) M forskolin stimulated aldosterone production and increased AS mRNA levels, though the effect of AII was greater. When cells were cultured with increasing concentrations of AII from 10(-11) through 10(-8) M, a dose-dependent increase in AS mRNA levels paralleled increases in aldosterone production. In view of these findings, these human adrenocortical cells should be useful for exploring mechanisms regulating aldosterone production.

Cloning and expression of phospholipase A2 from guinea pig gastric mucosa, its induction by carbachol and secretion in vivo

A cDNA encoding phospholipase A2 (PLA2) was cloned from guinea pig gastric mucosa using a rat pancreatic-PLA2-cDNA fragment as a probe. The cDNA contains an open reading frame sufficient to encode the entire amino-acid sequence of a PLA2-precursor protein consisting of 146 amino acids, including a putative 16-residue signal peptide and a 6-residue activation peptide at the NH2-terminus. Its nucleotide sequence exhibits 70% similarity to that of rat pancreatic PLA2 cDNA. The deduced amino-acid sequence has all the typical pancreatic PLA2 characteristics, with the exception of the substitution of Phe for Tyr at position 28 in the calcium-binding loop of the mature enzyme. When an expression vector containing the PLA2 cDNA was transfected into COS-7 cells, a major portion of the proenzyme was secreted into the culture medium. Northern-blot analysis showed the mRNA was present in guinea pig lung and pancreas at much lower levels than in the stomach. The effect of carbachol, a muscarinic acetylcholine agonist, on the secretion of gastric PLA2 and on its mRNA level in the gastric mucosa were examined. PLA2 secretion into the gastric juice was maximal 30 min after the subcutaneous administration of carbachol (0.4 mg/kg). It also increased the PLA2-mRNA level in the tissue, the maximal mRNA level being delayed about 15 min compared with that in PLA2 secretion. These results suggest that vagal stimuli may contribute to PLA2 secretion and its compensatory synthesis, and that the secreted PLA2 may participate in the digestion of dietary and biliary phospholipids in the small intestine of guinea pig.

Calf adrenocortical fasciculata cells secrete aldosterone when placed in primary culture

Aldosterone production occurs in the outer area of the adrenal cortex, the zona glomerulosa. The glucocorticoids cortisol and corticosterone, depending upon the species, are synthesized in the inner cortex, the zona fasciculata. Calf zona glomerulosa cells rapidly lose the ability to synthesize aldosterone when placed in primary culture unless they are incubated in the presence of the antioxidants butylated hydroxyanisol and selenous acid, the radioprotectant DMSO, and the cytochrome P-450 inhibitor metyrapone. In the presence of these additives, calf zona fasciculata cells in primary culture synthesize aldosterone at rates which can approach those from cells isolated from the zona glomerulosa. Calf zona glomerulosa and fasciculata cells both responded well to ACTH and angiotensin II, but the zona fasciculata cells respond very poorly compared to glomerulosa cells to increased potassium in the media. Rat zona fasciculata cells in primary culture under similar conditions did not synthesize aldosterone, suggesting that the regulation of the expression of the enzymes responsible for the biosynthesis of aldosterone in the two species is different. Two distinct cytochrome P-450 cDNAs which hydroxylate deoxycorticosterone at the 11 beta position have been described in the rat, human and mouse. Both cytochrome P-450 cDNAs have been cloned and expressed in non-steroidogenic cells, but only one is expressed in the zona glomerulosa and only this glomerulosal cytochrome P450 can further hydroxylate deoxycorticosterone to generate aldosterone. Two bovine adrenal cDNAs have been described with 11 beta-hydroxylase activity and their expression products in transiently transfected COS cells can convert deoxycorticosterone into aldosterone. Both enzymes are expressed in all zones of the adrenal cortex. Zonal regulation of aldosterone synthesis in the bovine adrenal gland may be due to an 11 beta-hydroxylase with aldosterone synthesizing capacity which has not yet been isolated. Alternatively, a single enzyme might be responsible for the several hydroxylations in the pathway between deoxycorticosterone and aldosterone and zonal synthesis might be controlled by unknown factors regulating the expression of C-18 hydroxylation. The incubation of zona fasciculata with antioxidants and metyrapone results in atypical expression of this activity by an unclear mechanism.

Linkage of 11 beta-hydroxylase mutations with altered steroid biosynthesis and blood pressure in the Dahl rat

In Dahl salt-hypertension sensitive (S) and resistant (R) strains fed a high NaCl diet, 11 beta-hydroxylase polymorphisms cosegregate with the adrenal capacity to synthesize 18-hydroxy-11-deoxycorticosterone (18-OH-DOC) and blood pressure. The R rat carries an 11 beta-hydroxylase allele that: (i) differs from those of 12 other rat strains; (ii) is associated with a uniquely reduced capacity to synthesize 18-OH-DOC; and (iii) encodes 5 amino acid substitutions in the 11 beta-hydroxylase protein. The robust salt-resistance of the Dahl R rat may be due in part to reduced synthesis of the mineralocorticoid 18-OH-DOC stemming from mutations in the 11 beta-hydroxylase gene. 11 beta-hydroxylase, located on rat chromosome 7, is the first candidate gene identified in an animal model in which coding sequence mutations have been linked to the regulation of blood pressure.

Final steps of aldosterone biosynthesis: molecular solution of a physiological problem

The final two steps of aldosterone biosynthesis play a key role in the complex physiological adaptation of aldosterone secretion to changes in sodium and potassium content of the mammalian organism. The nature and identity of the enzyme catalyzing these steps have only recently been established. In the rat as well as in the human adrenal, two types of cytochrome P-450(11 beta) are encoded by two different genes. The major type of the enzyme catalyzes only the conversion of deoxycorticosterone to corticosterone or 18-hydroxy-11-deoxycorticosterone; it is present in all the zones of the adrenal cortex. The second type of the enzyme catalyzes the three steps involved in the conversion of deoxycorticosterone to aldosterone and occurs only in the zona glomerulosa. In rat zona glomerulosa cells, separate control systems independently regulate the expression of the two genes, according to long-term in vivo experiments or to experiments with primary cultures of zona glomerulosa cells. Expression of the non-aldosterone-producing enzyme is induced by ACTH, whereas the expression of the aldosterone-producing enzyme is dependent on the extracellular potassium concentration.

Photoaffinity labeling of cytochrome P-45011 beta with methyltrienolone as a probe for the substrate binding region

Methyltrienolone, a synthetic steroid, was used as a photoaffinity ligand for steroid-binding proteins. The enzymatic activity of bovine adrenocortical cytochrome P-450(11) beta was inhibited by methyltrienolone in a competitive manner without exposure to light and cytochrome P-450(11) beta was photolabeled with methyltrienolone after irradiation with UV light. The addition of 11-deoxycorticosterone during photolabeling protected cytochrome P-450(11) beta from photolabeling. Photolabeled cytochrome P-450(11) beta was digested with TPCK-treated trypsin and the peptide fragments were separated with a reverse-phase HPLC system. The labeled peptide was analyzed and its amino acid sequence was determined to be Trp428-Leu429-Asp430-Arg431. Alignment of the primary structure of cytochrome P-450(11) beta with that of cytochrome P-450cam revealed that the identified sequence corresponds to the region between the beta 3-sheet and L-helix of cytochrome P-450cam. This region of mammalian cytochromes P-450 shows poor homology with that of cytochrome P-450cam, but is well-conserved, especially at Trp-428 and preceding amino acids, as the aromatic region. The present results demonstrate that the labeled sequence contributes in part to the formation of the substrate binding pocket of cytochrome P-450(11) beta which was not expected from the results of the primary sequence alignment with cytochrome P-450cam.

Two types of cytochrome P-450(11 beta) in rat adrenals: separate regulation of gene expression

Northern blot hybridization with specific oligonucleotide probes was used for assaying steady state concentrations of the mRNAs encoding the two types of rat cytochrome P-450(11 beta), i.e. CYP11B1 (non-aldosterone-producing) and CYP11B2 (aldosterone-producing). The zona glomerulosa level of CYP11B2 mRNA was raised by potassium repletion or sodium restriction and was lowered by potassium depletion or by the administration of deoxycorticosterone, ACTH or dexamethasone. In all zones of the adrenal cortex, the CYP11B1 mRNA level was decreased upon dexamethasone treatment. Only in the zona glomerulosa it was increased upon mineralocorticoid treatment and decreased upon potassium repletion or sodium restriction. According to this evidence, the expression of the two genes encoding the two isozymes (CYP11B1 and CYP11B2) in rat zona glomerulosa cells is separately regulated. Whereas CYP11B2 expression is controlled mainly by angiotensin II and extracellular potassium, ACTH is the major but not the only factor controlling CYP11B1 expression in these cells.

The P450 superfamily: update on new sequences, gene mapping, accession numbers, early trivial names of enzymes, and nomenclature

We provide here a list of 221 P450 genes and 12 putative pseudogenes that have been characterized as of December 14, 1992. These genes have been described in 31 eukaryotes (including 11 mammalian and 3 plant species) and 11 prokaryotes. Of 36 gene families so far described, 12 families exist in all mammals examined to date. These 12 families comprise 22 mammalian subfamilies, of which 17 and 15 have been mapped in the human and mouse genome, respectively. To date, each subfamily appears to represent a cluster of tightly linked genes. This revision supersedes the previous updates [Nebert et al., DNA 6, 1-11, 1987; Nebert et al., DNA 8, 1-13, 1989; Nebert et al., DNA Cell Biol. 10, 1-14 (1991)] in which a nomenclature system, based on divergent evolution of the superfamily, has been described. For the gene and cDNA, we recommend that the italicized root symbol "CYP" for human ("Cyp" for mouse), representing "cytochrome P450," be followed by an Arabic number denoting the family, a letter designating the subfamily (when two or more exist), and an Arabic numeral representing the individual gene within the subfamily. A hyphen should precede the final number in mouse genes. "P" ("p" in mouse) after the gene number denotes a pseudogene. If a gene is the sole member of a family, the subfamily letter and gene number need not be included. We suggest that the human nomenclature system be used for all species other than mouse. The mRNA and enzyme in all species (including mouse) should include all capital letters, without italics or hyphens. This nomenclature system is identical to that proposed in our 1991 update. Also included in this update is a listing of available data base accession numbers for P450 DNA and protein sequences. We also discuss the likelihood that this ancient gene superfamily has existed for more than 3.5 billion years, and that the rate of P450 gene evolution appears to be quite nonlinear. Finally, we describe P450 genes that have been detected by expressed sequence tags (ESTs), as well as the relationship between the P450 and the nitric oxide synthase gene superfamilies, as a likely example of convergent evolution.

Steroidogenic enzymes: structure, function, and role in regulation of steroid hormone biosynthesis

In the pathways of steroid hormone biosynthesis there are two major types of enzymes: cytochromes P450 and other steroid oxidoreductases. This review presents an overview of the function and expression of both types of enzymes with emphasis on steroidogenic P450s. The final part of the review on regulation of steroidogenesis includes a description of the normal physiological fluctuations in the steroid output of adrenal cortex and gonads, and provides an analysis of the relative role of enzyme levels in the determination of these fluctuations. The repertoire of enzymes expressed in a steroidogenic cell matches the cell's capacity for the biosynthesis of specific steroids. Thus, steroidogenic capacity is regulated mainly by tissue and cell specific expression of enzymes, and not by selective activation or inhibition of enzymes from a larger repertoire. The quantitative capacity of steroidogenic cells for the biosynthesis of specific steroids is determined by the levels of steroidogenic enzymes. The major physiological variations in enzyme levels, are generally associated with parallel changes in gene expression. The level of expression of each steroidogenic enzyme varies in three characteristics: (a) tissue- and cell-specific expression, determined during tissue and cell differentiation; (b) basal expression, in the absence of trophic hormonal stimulation; and (c) hormonal signal regulated expression. Each of these three types of expression probably represent the functioning of distinct gene regulatory elements. In adult steroidogenic tissues, the levels of most of the cell- and tissue-specific steroidogenic enzymes depend mainly on trophic hormonal stimulation mediated by a complex network of signal transduction systems.

In vivo regulation of gene expression of enzymes controlling aldosterone synthesis in rat adrenal

We studied the effect of alterations in the intake of sodium and potassium as well as changes in circulating adrenocorticotropin (ACTH) on the expression of the two rate-limiting systems of aldosterone formation in the rat. Low sodium and high potassium intake promoted time-dependent increases in the zona glomerulosa cytochrome P450scc (P450scc) and cytochrome P450c11 (P450c11) protein and mRNA levels, but no changes were found in the zona fasciculata-reticularis. In addition, these responses were associated with markedly elevated transcriptional activities. To further define the contribution of P450c11 and P450c18 (aldosterone synthase) in response to these differing intakes, we evaluated their mRNA levels using gene-specific oligonucleotide probes. P450c18 mRNA was restricted to the zona glomerulosa, whereas P450c11 mRNA was detected in both zona glomerulosa and zona fasciculata-reticularis. Furthermore, only P450c18 mRNA was induced by both low sodium or high potassium intake, as P450c11 mRNA levels remained unchanged. Captopril, an inhibitor of angiotensin-I converting enzyme, abolished the enhancing effects of the low sodium regimen on P450scc and P450c18 mRNA levels. Captopril also suppressed the augmentation of P450c18 mRNA observed with potassium supplementation but had no effect on P450scc mRNA levels. When the hypocholesterolemic drug 4-aminopyrazolopyrimidine (4-APP) was administered to rats for 3 consecurive days, both the level of plasma ACTH and the adrenal content of mRNA encoding P450scc increased 24 h post final injection. The coadministration of dexamethasone with 4-APP prevented these increases. In contrast, the mRNA content of P450c11 remained at control levels. In conclusion, this work demonstrates that variations in the intake of sodium and potassium act on the expression of the CYP11B2 gene, but not on that of the CYP11B1 gene. Moreover angiotensin-II (A-II) is an important factor in this mechanism of action. Both ions also enhance the expression of the CYP11A1 gene. A-II appears to participate in the mechanism of action of the low sodium intake at this level. Another mechanism is postulated for the action of potassium supplementation since captopril did not prevent the increased expression of the CYP11A1 gene. In addition, the fact that 4-APP enhanced the mRNA level of P450scc but not that of P450c, also demonstrates different regulation of the P450s involved at the early and final steps of aldosteroone formation in the rat adrenal zona glomerulosa in vivo.

Molecular biology of 11β-hydroxylase and 11β-hydroxysteroid dehydrogenase enzymes

There are two steroid 11β-hydroxylase isozymes encoded by the CYP11B1 and CYP11B2 genes on human chromosome 8q. The first is expressed at high levels in the normal adrenal gland, has 11β-hydroxylase activity and is regulated by ACTH. Mutations in the corresponding gene cause congenital adrenal hyperplasia due to 11β-hydroxylase deficiency; thus, this isozyme is required for cortisol biosynthesis. The second isozyme is expressed at low levels in the normal adrenal gland but at higher levels in aldosterone-secreting tumors, and has 11β-hydroxylase, 18-hydroxylase and 18-oxidase activities. The corresponding gene is regulated by angiotensin II, and mutations in this gene are found in persons who are unable to synthesize aldosterone due to corticosterone methyloxidase II deficiency. Thus, this isozyme is required for aldosterone biosynthesis. Cortisol and aldosterone are both effective ligands of the "mineralocorticoid" receptor in vitro, but only aldosterone is a potent mineralocorticoid in vivo. This apparent specificity occurs because 11β-hydroxysteroid dehydrogenase in the kidney converts cortisol to cortisone, which is not a ligand for the receptor. This enzyme is a "short-chain" dehydrogenase which is encoded by a single gene on human chromosome 1. It is possible that mutations in this gene cause a form of childhood hypertension called apparent mineralocorticoid excess, in which the mineralocorticoid receptor is not protected from high concentrations of cortisol.

Disorders of steroid 11 beta-hydroxylase isozymes

Steroid 11 beta-hydroxylase activity in the adrenal cortex is required for the synthesis of the major glucocorticoids and mineralocorticoids, but different isozymes mediate this conversion in the zona fasciculata, where cortisol is produced, and the zona glomerulosa, the site of aldosterone synthesis. The isozyme in the latter zone also has 18-hydroxylase and 18-oxidase activities that are required for aldosterone synthesis. Mutations in the genes encoding these isozymes respectively result in defective synthesis of cortisol and aldosterone. Recombinations between the two genes that alter the regulation of the isozyme responsible for aldosterone synthesis cause an inherited form of hypertension, glucocorticoid-suppressible hyperaldosteronism.

Mutations in the human CYP11B2 (aldosterone synthase) gene causing corticosterone methyloxidase II deficiency

Corticosterone methyloxidase II (CMO-II) deficiency is an autosomal recessive disorder of aldosterone biosynthesis, characterized by an elevated ratio of 18-hydroxycorticosterone to aldosterone in serum. It is genetically linked to the CYP11B1 and CYP11B2 genes that, respectively, encode two cytochrome P450 isozymes, P450XIB1 and P450XIB2. Whereas P450XIB1 only catalyzes hydroxylation at position 11 beta of 11-deoxycorticosterone and 11-deoxycortisol, P450XIB2 catalyzes the synthesis of aldosterone from deoxycorticosterone, a process that successively requires hydroxylation at positions 11 beta and 18 and oxidation at position 18. To determine the molecular genetic basis of CMO-II deficiency, seven kindreds of Iranian-Jewish origin were studied in which members suffered from CMO-II deficiency. No mutations were found in the CYP11B1 genes, but two candidate mutations, R181W and V386A, were found in the CYP11B2 genes. When these mutations were individually introduced into CYP11B2 cDNA and expressed in cultured cells, R181W reduced 18-hydroxylase and abolished 18-oxidase activities but left 11 beta-hydroxylase activity intact, whereas V386A caused a small but consistent reduction in the production of 18-hydroxycorticosterone. All individuals affected with CMO-II deficiency were homozygous for both mutations, whereas eight asymptomatic subjects were homozygous for R181W alone and three were homozygous for V386A alone. These findings confirm that P450XIB2 is the major enzyme mediating oxidation at position 18 in the adrenal and suggest that a small amount of residual activity undetectable in in vitro assays is sufficient to synthesize normal amounts of aldosterone.

The differential regulation of aldosterone output in hamster adrenal by angiotensinII and adrenocorticotropin

Aldosterone was isolated from hamster adrenal cells and was identified by high performance liquid chromatography and thermospray mass spectroscopy analysis. Basal outputs from adrenal cell suspensions were of the same order of magnitude, 8.4 +/- 1.9 ng and 8.0 +/- 0.7 ng/2 h/50,000 cells, for aldosterone and corticosteroid, respectively. The outputs of aldosterone and corticosteroid increased with K+ concentrations to reach maxima of 3.3- and 1.6-fold at 10 meq/l of K+. AngiotensinII (AII) produced dose-dependent increases in aldosterone and corticosteroid outputs with maxima of 3- and 4-fold, respectively. In contrast, ACTH induced relatively no changes in aldosterone output, whereas dose-dependent increases in corticosteroid output were found. In time study experiments, with 10(-8) M AII, aldosterone and corticosteroid outputs were maximally increased after 1 h (6-fold) and 3 h (1.8-fold), respectively. At 10(-8) M, ACTH had a small stimulatory effect on aldosterone output after 6 h, whereas it provoked a gradual increase in corticosteroid output (up to 7-fold after 8 h of incubation). The effects of AII and ACTH on adrenal cytochrome P-450(11 beta) involved in the last steps of aldosterone formation were evaluated by combined in vivo and in vitro experiments. The P-450(11 beta) mRNA level was increased by a low sodium intake but not by a 24 h ACTH stimulus. These results taken together indicate that ACTH and AII differentially regulate P-450(11 beta). It is postulated that these two regulatory peptides regulate the hamster adrenal steroidogenesis by different P-450 genes.

Functional expression of cDNAs for bovine 11 beta-hydroxylase-aldosterone synthases, P450(11 beta)-2 and -3 and their chimeras

Two molecular species of bovine P450(11 beta), P450(11 beta)-2 and P450(11 beta)-3 have been identified, in which the amino acid differences were found at the 6th, 36th and 82nd positions from the NH2-termini of the mature proteins. They catalyzed the 11 beta-, 18- and 19-hydroxylation and aldosterone formation from 11-deoxycorticosterone, and the rate of production of 18-hydroxycorticosterone and aldosterone by P450(11 beta)-3 was greater than that by P450(11 beta)-2 [Morohashi et al., J. Biochem. 107 (1990) 635-640]. In this study, chimeric clones were constructed whose 6th, 36th and 82nd amino acid residues were exchanged with each other. Two original clones and six chimeric clones were expressed in COS-7 cells, and their steroidogenic activities studied. The ratio of aldosterone or 18-hydroxycorticosterone production to corticosterone production by one clone was compared with that of the other. The ratios for the four clones having Gly36 [P450(11 beta)-3 type] were 0.08-0.22, whereas those for the clones having Ser36 [P450(11 beta)-2 type] were 0.03-0.05, suggesting that the Gly36 structure is important for aldosterone production.

Molecular biology of rat steroid 11 beta-hydroxylase [P450(11 beta)] and aldosterone synthase [P450(11 beta, aldo)]

The molecular features of rat steroid 11 beta-hydroxylase [P450(11 beta)] and aldosterone synthase [P450(11 beta, aldo)] are discussed. P450(11 beta) is biosynthesized as a precursor form composed of 499 amino acids, having a 24-amino acid extension peptide. Two species of P450(11 beta, aldo) were identified; a precursor form of P450(11 beta, aldo)-1 is 510 amino acids long and has a 34-amino acid extension peptide, while that of P450(11 beta, aldo)-2 is 500 amino acids long and has a 24-amino acid extension peptide. The 286th amino acid of P450(11 beta, aldo)-1 is Glu, while that of P450(11 beta, aldo)-2 is Lys. The cDNA-expression studies showed that P450(11 beta, aldo)-1 had the aldosterone producing activity whereas P450(11 beta, aldo)-2 had no activity, suggesting that Glu286 of P450(11 beta, aldo) plays an important role in the catalysis. The amino acid sequence of a region in P450(11 beta) from Leu337 through Pro352 is highly conserved among the steroidogenic P450s. Functional expression studies on the cDNAs for two P450(11 beta)s showed that P450(11 beta) catalyzes the 11 beta-, 18- and 19-hydroxylations of 11-deoxycorticosterone, but not the aldosterone synthesis. P450(11 beta, aldo), on the other hand, catalyzes the conversion of 11-deoxycorticosterone to corticosterone, 18-hydroxycorticosterone and aldosterone. The two P450(11 beta)s were also shown to catalyze the conversion of 11-deoxycortisol to cortisol, 18-hydroxycortisol and cortisone.

Influence of captopril on adrenal cytochrome P-450s and adrenodoxin expression in high potassium or low sodium intake

To investigate the role of the renin-angiotensin system in steroidogenic enzyme expression, the angiotensin-I converting enzyme inhibitor captopril was administered in conjunction with high potassium (K+) or low (Na+) intake to rats for a 7-day period. Northern blot analysis of adrenocortical zona glomerulosa RNA revealed that sodium restriction markedly increased mRNA production of P-450scc (3.1-fold) and P-450(11 beta) (3.4-fold) as well as of the electron donor adrenodoxin (2.0-fold). Captopril combined to the low Na+ diet led to suppression of these effects and, as also seen with captopril alone, further diminished P-450(11 beta) mRNA levels below controls. These responses were accompanied by parallel changes in respective protein levels of the enzymes as indicated by Western blot analyses. Captopril was also shown to inhibit the K(+)-stimulated levels of P-450(11 beta) mRNA (3.3-fold) and protein (1.4-fold) beneath control values (0.6- and 0.8-fold, respectively). On the other hand, increased P-450scc mRNA and protein levels by K+ loading were not affected by captopril treatment. No response was observed in any steroidogenic enzyme expression in zona fasciculata-reticularis following either diet with or without captopril. Thus, the inhibitory effect of captopril on stimulated steroidogenesis seemed to be mediated in part through transcriptional regulation of P450s. In addition, it appeared that P-450(11 beta) expression might be under the control of the renin-angiotensin system in both high K+ and low Na+ diets as opposed to the K+ stimulation of P-450scc where other mechanisms seemed to be involved.

Functional expression of the cDNAs encoding rat 11 beta-hydroxylase [cytochrome P450(11 beta)] and aldosterone synthase [cytochrome P450(11 beta, aldo)]

Expression plasmids containing two cDNAs of a rat cytochrome P450(11 beta) family, pcP450(11 beta)-62 [Nonaka, Y., Matsukawa, N., Morohashi, K., Omura, T., Ogihara, T., Teraoka, H. & Okamoto, M. (1989) FEBS Lett. 255, 21-26] and pcP450(11 beta, aldo)-46 [Matsukawa, N., Nonaka, Y., Ying, Z., Higaki, J., Ogihara, T. & Okamoto, M. (1990) Biochem. Biophys. Res. Commun. 169, 245-252], were constructed and introduced into COS-7 cells by electroporation. Enzymatic activities of the expressed cytochromes P450(11 beta) and P450(11 beta, aldo) were determined by using 11-deoxycorticosterone, corticosterone, 18-hydroxy-11-deoxycorticosterone, 18-hydroxycorticosterone, or 19-hydroxy-11-deoxycorticosterone as a substrate. Cytochrome P450(11 beta) catalyzed 11 beta-, 18- and 19-hydroxylations of 11-deoxycorticosterone and 19-oxidation or 19-hydroxy-11-deoxycorticosterone at substantial rates, 18-hydroxylation of corticosterone at a very low rate, but no aldosterone production. Cytochrome P450(11 beta, aldo) catalyzed 11 beta- and 18-hydroxylations of 11-deoxycorticosterone, 18-hydroxylation of corticosterone and aldosterone production from 11-deoxycorticosterone or corticosterone. But neither 19-hydroxylation of 11-deoxycorticosterone nor 19-oxidation of 19-hydroxy-11-deoxycorticosterone was catalyzed by cytochrome P450(11 beta, aldo).

Structural differences in 5'-flanking regions of rat cytochrome P-450aldo and P-450(11) beta genes

Two rat genomic clones, one for cytochrome P-450aldo and the other for P-450(11) beta, were isolated and characterized. The two genes, encoding structurally homologous proteins, were closely similar in their intron-exon organizations. Their 5'-flanking regions, however, contained only a few homologous regions. A putative cyclic AMP responsive element, TGACGTGA, was found in the P-450aldo gene, but this sequence was altered at two positions in the P-450(11) beta gene. S1 nuclease protection assay revealed a single transcription initiation site for the P-450aldo gene, while multiple sites were found for the P-450(11) beta gene. These results suggest that transcriptional regulation of the rat P-450aldo and P-450(11) beta genes is due to differences in the sequences of their 5'-flanking regions.

Localization of the gene transcripts of 11 beta-hydroxylase and aldosterone synthase in the rat adrenal cortex by in situ hybridization

Using in situ hybridization, localization of the gene transcripts of 11 beta-hydroxylase and aldosterone synthase was investigated in order to clarify the sites for the synthesis of corticosterone (glucocorticoid) and aldosterone (mineralocorticoid) in the rat adrenal cortex. The gene transcript of 11 beta-hydroxylase was localized in all the endocrine cells of the entire adrenal cortex, while that of aldosterone synthase was exclusively confined in zona glomerulosa cells. These results represent that every endocrine cell of all the cortical zones synthesizes 11 beta-hydroxylase which converts 11-deoxycorticosterone to corticosterone, and only glomerulosa cells synthesize aldosterone synthase which produces aldosterone from corticosterone. Thus it is clearly shown that zona glomerulosa cells synthesize mineralocorticoid, while zona fasciculata as well as reticularis cells produce glucocorticoid.

Zone-specific regulation of two messenger RNAs for P450c11 in the adrenals of pregnant and nonpregnant rats

Adrenal mitochondria possess two steroidogenic cytochrome P450s. P450c11 converts deoxycorticosterone to corticosterone and aldosterone, and P450scc converts cholesterol to pregnenolone. These P450s receive electrons from NADPH via adrenodoxin reductase and adrenodoxin. A single bovine P450c11 protein has 11-hydroxylase, 18-hydroxylase, and 18-oxidase activities, but this series of enzymatic steps may be mediated by more than one enzyme in rats. Enzymatic assays of purified rat mitochondrial proteins have suggested that one enzyme found in all zones of the adrenal cortex has both 11- and 18-hydroxylase activities, whereas another enzyme, found exclusively in the zona glomerulosa, catalyzes 18-hydroxylation and 18-oxidation of corticosterone. We studied the number and zonal distribution of P450c11 mRNA species in the rat adrenal and how these mRNAs are regulated in the adrenals of normal and pregnant rats. Rats synthesize two similar, but distinct, P450c11 mRNAs. One, P450c11A, is found in both the zona glomerulosa and fasciculata/reticularis, whereas the second, P450c11B, is found only in the zona glomerulosa. The abundance of neither P450c11A mRNA nor P450c11B mRNA is affected by a high-salt diet. However, when rats receive a low-salt diet, P450c11A mRNA decreases and P450c11B mRNA increases. Dexamethasone decreases the amount of P450c11A mRNA without affecting P450c11B mRNA. The combination of a high-salt diet and dexamethasone decreases the amount of both mRNAs further to almost undetectable amounts. Rats given a low-salt diet and dexamethasone have a dramatic increase in the abundance of P450c11B mRNA. Thus both forms of P450c11 mRNA are regulated independently in the rat adrenal cortex. In situ hybridization studies show that only the P450c11 found in the zona glomerulosa is regulated by salt treatment in vivo, whereas glucocorticoid treatment in vivo regulates P450c11 in all zones. In the adrenals of pregnant rats, P450c11B is regulated in a similar fashion to its regulation in the nonpregnant rat adrenal, despite major differences in sodium retention and intravascular volume in pregnant and nonpregnant rats. In the pregnant rat, a low-salt diet increases the abundance of P450c11B to a greater degree than in the nonpregnant rat. By contrast, dexamethasone does not diminish the abundance of P450c11A mRNA in the pregnant rat but reduces it to an almost undetectable amount in the nonpregnant rat. Thus, the regulation of glucocorticoid and mineralocorticoid production in the pregnant and nonpregnant rat occurs by different mechanisms.

A mutation in CYP11B1 (Arg-448----His) associated with steroid 11 beta-hydroxylase deficiency in Jews of Moroccan origin

Steroid 11 beta-hydroxylase (P450c11) deficiency (failure to convert 11-deoxycortisol to cortisol) causes less than 10% of cases of congenital adrenal hyperplasia in most populations, but it is relatively frequent in Jews of Moroccan origin. P450c11 is encoded by the CYP11B1 gene which is located on chromosome 8q22 along with a homologous gene of unknown function, CYP11B2. To identify mutations in CYP11B1 associated with 11 beta-hydroxylase deficiency in Moroccan Jews, oligonucleotides were used that selectively amplified portions of CYP11B1 in polymerase chain reactions without amplifying CYP11B2. Sequence analysis of amplified fragments from one patient revealed a single base substitution in exon 8, codon 448 from CGC (arginine) to CAC (histidine). This residue is within the "heme binding" peptide that contains a cysteine that is a ligand to the heme group. The equivalent of Arg-448 is found in every known eukaryotic P450, and therefore it seems likely that a mutation of this residue would adversely affect enzymatic activity. 11 of 12 affected alleles from six Moroccan Jewish families carried the mutation in codon 448. This mutation is not normally present in CYP11B2 and thus appears to have arisen in CYP11B1 as a true point mutation rather than a gene conversion.

The P450 superfamily: update on new sequences, gene mapping, and recommended nomenclature

We provide here a list of 154 P450 genes and seven putative pseudogenes that have been characterized as of October 20, 1990. These genes have been described in a total of 23 eukaryotes (including nine mammalian and one plant species) and six prokaryotes. Of 27 gene families so far described, 10 exist in all mammals. These 10 families comprise 18 subfamilies, of which 16 and 14 have been mapped in the human and mouse genomes, respectively; to date, each subfamily appears to represent a cluster of tightly linked genes. We propose here a modest revision of the initially proposed (Nebert et al., DNA 6, 1-11, 1987) and updated (Nebert et al., DNA 8, 1-13, 1989) nomenclature system based on evolution of the superfamily. For the gene we recommend that the italicized root symbol CYP for human (Cyp for mouse), representing cytochrome P450, be followed by an Arabic number denoting the family, a letter designating the subfamily (when two or more exist), and an Arabic numeral representing the individual gene within the subfamily. A hyphen should precede the final number in mouse genes. We suggest that the human nomenclature system be used for other species. This system is consistent with our earlier proposed nomenclature for P450 of all eukaryotes and prokaryotes, except that we are discouraging the future use of cumbersome Roman numerals.

Elevated 18-hydroxy-corticosterone in inbred salt-sensitive rats

Rats susceptible to the hypertensive effect of dietary salt (SS/Jr) have excess 18-hydroxydeoxycorticosterone (18-OH-DOC) and 19-nor-DOC compared to control rats (SR/Jr). This may be caused by an abnormal adrenal 11 beta-hydroxylase, which catalyzes the 11 beta, 18, and 19-hydroxylations of DOC. A comparison of the urinary products of this enzyme including 18-OH-DOC, 19-nor-DOC, corticosterone (B), and 18-OH-B have not been described in the SS/Jr. Therefore, these steroid products were measured at 7 and 12 weeks of age in 36 weanling male and female, SS/Jr and SR/Jr (n = 9 in each group), on a low-salt diet. In both the male and female SS/Jr urinary free levels of 18-OH-DOC, 19-nor-DOC, and 18-OH-B were elevated, while B was not different at 6 and 10 weeks of age. The largest increases were in 18-OH-B levels, and these levels correlated with 18-OH-DOC and B but not 19-nor-DOC. The high degree of correlation between these steroids probably reflects their closely related dependence on adrenal 11 beta-hydroxylase biosynthesis.

Defects in cortisol metabolism causing low-renin hypertension

Deficiency of steroid 11 beta-hydroxylase, which is a mitochondrial cytochrome P450 required for cortisol and aldosterone synthesis, causes hypertension as well as virilization. In addition, abnormal regulation of this enzyme or a closely related isozyme may be involved in an autosomal dominant form of inherited hypertension, dexamethasone-suppressible hyperaldosteronism. An enzyme that catalyzes the interconversion of cortisol and cortisone, 11 beta-hydroxysteroid dehydrogenase, may be defective in an autosomal recessive form of hypertension termed apparent mineralocorticoid excess. The molecular bases of these forms of hypertension will be elucidated by identifying mutations in the 11 beta-hydroxylase and 11 beta-hydroxysteroid dehydrogenase genes and expressing normal and mutagenized enzymes in cultured cells.

Molecular nature of aldosterone synthase, a member of cytochrome P-450(11 beta) family

The molecular nature of the aldosterone synthesizing enzymes of cattle and rat is discussed. In bovine adrenal cortex, one molecular species of cytochrome P-450(11 beta) catalyzes aldosterone synthesis as well as 11 beta-hydroxylation. The intactness of the mitochondrial membrane surrounding P-450(11 beta) in the zonae fasciculata-reticularis is essential to keep the aldosterone synthesizing activity of the cytochrome in these zones latent. In rat adrenal cortex, two distinct molecules belonging to a P-450(11 beta) family exist. One is 11 beta-hydroxylase, and the other aldosterone synthase.

Two forms of cytochrome P-450(11 beta) in rat zona glomerulosa cells: a short review

Aldosterone, the major mineralocorticoid hormone, is produced exclusively in the zona glomerulosa of the mammalian adrenal cortex. In the rat species, this zonal specificity of aldosterone biosynthesis appears to be due mainly to the existence of a second form of cytochrome P-450(11 beta), which differs from the major form of the enzyme (molecular weight 51,000) by (1) a lower molecular weight (49,000), (2) a broader range of catalytic activities, which include corticosterone methyl oxidation 1 and 2, (3) an exclusive occurrence in the zona glomerulosa, and (4) a crucial dependence on sodium and potassium intake. The 49K form of the enzyme can be induced by potassium ions in vivo (potassium repletion of potassium-deficient rats) or in vitro (primary cell culture). The biosynthesis of this protein is controlled most likely at the level of transcription. According to indirect evidence, ACTH induces only the 51K form of the enzyme in vitro. Prolonged treatment of rats with a high dose of ACTH has a repressive effect on the 49K form of the enzyme.

Cloning and expression of a cDNA for human cytochrome P-450aldo as related to primary aldosteronism

A cDNA clone encoding human aldosterone synthase cytochrome P-450 (P-450aldo) has been isolated from a cDNA library derived from human adrenal tumor of a patient suffering from primary aldosteronism. The insert of the clone contains an open reading frame encoding a protein of 503 amino acid residues together with a 3 bp 5'-untranslated region and a 1424 bp 3'-untranslated region to which a poly(A) tract is attached. The nucleotide sequence of P-450aldo cDNA is 93% identical to that of P-450(11) beta cDNA. Catalytic functions of these two P-450s expressed in COS-7 cells are very similar in that both enzymes catalyze the formation of corticosterone and 18-hydroxy-11-deoxycorticosterone using 11-deoxycorticosterone as a substrate. However, they are distinctly different from each other in that P-450aldo preferentially catalyzes the conversion of 11-deoxycorticosterone to aldosterone via corticosterone and 18-hydroxycorticosterone while P-450(11)beta substantially fails to catalyze the reaction to form aldosterone. These results suggest that P-450aldo is a variant of P-450(11)beta, but this enzyme is a different gene product possibly playing a major role in the synthesis of aldosterone at least in a patient suffering from primary aldosteronism.